RU77031U1 - THERMOSTAT - Google Patents

Abstract

The utility model relates to the field of heat engineering devices, for example, thermostats, refrigerators, incubators. A thermostat, mainly for placing unified elements, comprising a housing, a thermally insulated working chamber made in the form of a hollow, open parallelepiped on one side, and laying for placing elements made in the form of hollow, open upright parallelepipeds, the dimensions of the working chamber being such that nine possible ratios of the internal dimensions of the working chamber, determining its width, depth and height, to the external dimensions of the stacks, determining their width, depth and height, at least three relationships selected as the first criteria relationship are in the range from before where - the integer part of the number of the first selected criteria relationship, . The technical result of the utility model is to increase the value of the coefficient of useful use of the space of the working chamber when unified elements, for example, containers with a biological product, are placed in its sections. 3 s.p. f-ly, 6 ill.

Description

The utility model relates to the field of heat engineering devices, for example, refrigeration thermostats, incubator thermostats, designed to store unified elements, for example, containers in the form of glass bottles or plastic bags with stored or cultured biological products, such as donated blood components and preparations, packages of the same form with medicinal and immunobiological substances, etc.

The closest in technical essence and the achieved result to the proposed thermostat is a refrigerator in the form of a cabinet, containing a housing, a heat-insulated working chamber, made in the form of a hollow, open parallelepiped open on one side, divided by shelves into sections, in which there are placed in the form of containers for placement with the purpose of storing elements, for example, products made in the form of hollow, open top parallelepipeds. (GB 1085044 class. F25D 25/02 09/27/1967).

A disadvantage of the known thermostat, taken as a prototype, is the low value of the efficiency of the volume of the working chamber, determined from the ratio

,

where V is the _capacitance and V is _working , respectively, is the volume of the element, for example, the capacity of the biological product and the volume of the working chamber of the apparatus;

N is the number of elements.

This disadvantage is due to the fact that the external dimensions of the elements intended for placement in the working chamber are not connected in any way with the internal dimensions - the depth, width, height of both the working chamber and its sections. In turn, this causes the appearance of free space gaps in the sections of the working chamber, smaller sizes of unified elements into which the latter cannot be laid.

The use of containers in a known thermostat for placing elements in the form of containers, the dimensions of which are not related to the dimensions of the containers, further aggravate the above.

In addition, the implementation of the placement in the working chamber in an arbitrary way thermostatically controlled elements determines, in turn, additional volumetric non-isothermal and the implementation of unequal temperature conditions in each of them.

The objective of the utility model is to increase the value of the coefficient of useful use of the space of the working chamber when unified elements, for example, containers with a biological product, are placed in its sections.

The specified technical result is achieved by the fact that the thermostat contains a housing, a thermally insulated working chamber made in the form of a hollow, open parallelepiped on one side, laying for placing elements made in the form of hollow, open parallelepipeds on top. The dimensions of the working chamber of the working chamber are such that out of nine possible ratios of the internal dimensions of the working chamber, determining its width, depth and height, to the external dimensions of the stacks, determining their width, depth and height, at least the values of three relations selected as the first criteria relationship are in the range from before where - the integer part of the number of the first selected criteria relationship, . Laying can be performed with the possibility of placing the elements in a vertical position, the external overall dimension of the laying, determining its height, is made not less than the height of the element, and the values of the ratios of the internal dimensions of the laying, determining its width and depth, to the external dimensions of the elements, determining their thickness and width selected as the second criteria relationship are in the range from before where - the whole part of the second selected criteria relationship, . The housing can be made in the form of a cabinet, the working chamber is divided into sections by the shelves, the height of at least one section is made not less than the laying height, and the ratios of the inner width of the working chamber to the outer width of the laying and the inner depth of the working chamber are selected as the first criteria relations to the outside laying depth. The housing can be made in the form of a chest, and the ratios of the internal width of the working chamber to the external width of laying, the internal height of the working chamber to the external height of laying, the internal depth of the working chamber to the external laying depth, are selected as the first criteria relations.

The essence of the utility model is illustrated by graphic material. For concretization, unified elements of the same type were selected for various biological products, donated blood, plasma, albumin, physiological solutions, etc. used in medical practice - bottles, polymer bags. Figure 1 presents a modification of the styling to accommodate polymer bags, front view; figure 2 is a side view of this installation; figure 3 presents a modification of the styling for placing bottles; figure 4 is a side view of this styling; figure 5 presents the thermostat in the form of a heating cabinet, in the sections of which are placed with unified containers in the form of polymer bags with a biological product; figure 6 presents the thermostat in the form of a chest, in

the working chamber of which is placed by stacking stacking with the same type of glass bottles filled with biological product.

The proposed thermostat contains an outer casing 1 with a door 2, a working chamber 3, fenced from the casing 1 by layers of insulation 4. In the thermostat embodiment in the form of a cabinet (Fig. 5), the working chamber 3 is divided by shelves 5 into sections 6, in which 7 c unified containers 8 filled with bio-product.

In the embodiment of the thermostat in the form of a chest (Fig. 6), the working chamber 3 is divided by vertical partitions 9 into sections, in which there are stacks 7, structurally made with the possibility of stacking one on top of the other.

As can be seen from figure 5, the internal size of the working chamber 3, determining its depth made in excess of a multiple of the outer overall length of the laying 7 , the internal size of the working chamber 3, determining its width made in excess of a multiple of the outer overall width of the laying 7 and the height of the section 6 is made not less than the size that determines the overall height of the laying 7.

Similarly, from Fig.6 it can be seen that the internal size of the working chamber 3 of the thermostat, made in the form of a chest, determining its depth made in excess of a multiple of the outer overall height of the laying 7 , the internal size of the working chamber 3, determining its length made in excess of a multiple of the outer overall length of the laying 7 and the width of the vertical section 6 of the working chamber 3 is made not less than the overall width of the laying 7.

In turn, the internal laying size is 7 along the length made in excess of a multiple of one of the dimensions of the tank 8 (or thickness or width ), and at the same time, the other internal laying size 7 is the width performed in excess of a multiple of another overall dimension of the tank 8 (or the width or thickness and the installation height is not less than the height

containers 8.

The size of the technological gap, which should be provided between the laying 7 when designing the thermostat, placed in the volume of the working chamber 3, can determine either their very dense layout in sections 6, which corresponds to the minimum value or determine their arrangement in sections 6 with the possibility of ensuring the necessary air circulation .

With a uniform spreading of piling 7 in section 6, you can write:

From equality (A) we can obtain:

In its turn,

From equalities (B) and (C) it follows:

As an example, we determine the possible ranges of the size of the gaps when using stacking 7 with overall dimensions:

width = 150 mm

length = 500 mm.

Stacking 7 placed in 3 pieces. along the width of the shelves 5 sections 6 of the thermostat in the form of a cabinet and 2 pcs. along the depth of the shelves 5.

When n ₁ = 3 value is in the range from 0.0025 to 0.27; accordingly, the gap between the pitches across the width of section 6 defined by claim 1 of the claims (utility model) is in the range from 0.4 mm to 30 mm.

When n ₁ = 2 value is in the range from 0.0033 to 0.27; accordingly, the gap between the stacks 7 along the depth of section 6, defined by claim 1 of the claims (utility model) is in the range from 1.25 mm to 135 mm.

Thus, the range of values of K ₁ given in claim 1 of the claims (utility model) determines both the very dense and structurally necessary packing of the packs 7 along the depth of the working chamber 3, and the packaging, which allows providing the necessary level of air circulation in the working chamber 3 for implementation of the required degree of volumetric isothermality.

Similarly, the range of values of K ₂ given in paragraph 2 of the claims (utility model) determines the necessary criterion for the packing density of containers in a stack, and higher than the packing criterion for stacks in a chamber.

The thermostat includes a controlled heat exposure unit (not shown in the drawings), through which a predetermined temperature regime is provided in the working chamber 3, which, depending on the selected electronic thermal circuit, can be, for example:

- heater;

- panel evaporators (not shown in the drawing) of the compression refrigeration unit (not shown in the drawing), integrated in the shelves 5;

- a compact evaporator (not shown in the drawing) of a compression refrigeration unit located in an air channel in which a forced air flow is created;

- a radiator (not shown in the diagram) connected to the heat-acting surface of the semiconductor thermal module (not shown in the diagram), which implements the Peltier effect, etc.

The operation of the proposed thermostat depends on the electronic thermal circuit used, the type of heat exposure unit, and boils down to providing predetermined time characteristics of unsteady temperature processes when entering the mode, to the dosage of heat exposure, a certain direction when implemented with the required accuracy in the working chamber 3 of the preset temperature control mode .

The application of the proposed thermostat is as follows.

Unified containers 8 with biological product (for example, polymer bags filled with donor blood components, bottles) to be thermostated, placed in stacks 7.

Since the width of the inner cavity of the stacking 7 is made approximately a multiple of the outer overall width of the container 8, rows of N ₁ containers 8 are formed inside the stacking 7, where the number N ₁ , depending on the overall width of the container 8, is

The number of rows of N2 containers 8 inside the stack 7 is:

Laying 7, filled with containers 8, is placed in section 6, the height of which, i.e. the distance between adjacent shelves 5 is made equal to the height of the stacking 7. Moreover, on each shelf 5 are placed N ₃ × N ₄ stackings, where

If it is necessary to place in a working chamber for long-term storage a large number of containers of the same type with a biological product, for example, polymer bags containing 0.25 ÷ 0.3 l of blood plasma during quarantine at a temperature of minus (30 ÷ 40) ° С, all sections of the working camera apparatus can be made of the same height, determined by the height of the tank. In this case, the number of tanks

placed in the working chamber of the apparatus, is N ₁ × N ₂ × N ₃ × N ₄ × N ₅ , where N ₅ is the number of sections.

Due to the fact that in the proposed thermostat, the corresponding dimensions of the containers, stacks, sections of the working chamber are interconnected in the manner described above, the efficiency of the volume of the working chamber reaches the maximum possible value.

In addition, in the proposed thermostat, the spatial orientation of the containers with bioproducts in the working chamber is not arbitrary, which is observed in known thermostats, but is strictly vertical, namely, as provided for by the relevant regulatory documents.

Claims (4)

1. The thermostat mainly for storing unified elements, containers, for example, with a thermosensitive biological substance, comprising a housing, a heat-insulated working chamber, made in the form of a hollow, open on one side of the parallelepiped, styling for placing elements, made in the form of hollow, open on top of the parallelepipeds, the dimensions of the working chamber are made such that out of nine possible ratios of the internal dimensions of the working chamber, determining its width, depth and height, to the external dimensions dock, defining their width, depth and height, at least the values of the three relations

selected as the first criteria relationship are in the range from

before

where

- the integer part of the number of the first selected criteria relationship,

. 2. The thermostat according to claim 1, characterized in that the installation is arranged to place the elements in an upright position, the external overall dimension of the installation, determining its height, is made not less than the height of the element, and the values of the ratios of the internal installation dimensions, determining its width and depth, to the outer dimensions of the elements that determine their thickness and width, selected as the second criteria relations

are in the range from

before

where

- the whole part of the second selected criteria relationship,

. 3. The thermostat according to claim 1, characterized in that the casing is made in the form of a cabinet, the working chamber is divided into sections by the shelves, the height of at least one section is made not less than the laying height, and the relations of the internal working width are selected as the first criteria relations chamber to the external width of the laying and the internal depth of the working chamber to the external depth of the laying. 4. The thermostat according to claim 1, characterized in that the casing is made in the form of a chest, and the ratios of the internal width of the working chamber to the external width of laying, the internal height of the working chamber to the external height of laying, the internal depth of the working chamber to the outer, are selected as the first criterion relations laying depth.